BACKGROUND OF THE INVENTION
Field of the Invention:
[0001] The present invention relates to a method and an apparatus for electrostatic powder
coating, whereby charged powder is electrostatically applied to the surface of an
object to be coated, especially an object to be coated which has an undercoat insulating
layer.
Description of the Related Art:
[0002] From the viewpoint of environmental protection, electrostatic powder coating has
been attracting attention as a nonpolluting coating method to replace solvent coating.
The electrostatic powder coating is a method whereby powder, which is carried by air,
is sprayed from an electrostatic gun toward a grounded object to be coated. The powder
is charged before it is applied to the surface of the object to be coated. The method
for charging such powder is divided roughly into types: in one type of the method,
the powder is charged outside the electrostatic gun after it is sprayed from the electrostatic
gun; in the other type, the powder is charged inside the electrostatic gun before
it is sprayed from the electrostatic gun.
[0003] A corona gun 1 is known as an electrostatic gun based on the external charging method.
The tip of the corona gun 1 is provided with a pin-shaped corona electrode 2 to which
high voltage is applied. An object to be coated 3 is grounded; therefore, when corona
discharge is given from the tip of the gun 1 toward the object to be coated 3, causing
powder to be carried by air and sprayed from the gun 1, the ions generated by the
corona discharge adhere to the powder particles to charge them. After that, the charged
powder particles adhere to the surface of the object to be coated 3 under the influences
exerted by an air stream from the gun 1 and the electric force given along the lines
of electric force 4.
[0004] As shown in Fig. 17, however, the lines of electric force 4 are concentrated on a
projecting section of the object to be coated 3 and very few lines of electric force
enter a recessed section due to the Faraday cage effect. Hence, the powder particles
concentrate on and stick mainly to the projecting section. This means that a powder
particle layer 5 is formed mostly on the projecting section and it is hardly formed
on the recessed section. Further, of the ions produced by the corona discharge, barely
half of them adhere to the powder particles and most ions stay as free ions and move
along the lines of electric force 4 to adhere to the surface of the object to be coated
3. As the powder particle layer 5 is formed on the object to be coated 3, the free
ions also accumulate on the object to be coated 3. This causes the surface potential
of the object to be coated 3 to gradually increase and the transfer efficiency of
the powder particles gradually decreases with the increasing surface potential. As
a result, the intensity of the electrical field in the powder particle layer 5 increases
and when it exceeds the dielectric breakdown electric field intensity level of air,
the back ionization phenomenon, wherein minute discharge takes place in the powder
particle layer 5, happens with a consequent rough surface of a coating film.
[0005] A tribogun 9 shown in Fig. 18 is known as an electrostatic gun based on the internal
charging method. Powder particles which are carried by air in the gun are charged
by the friction with a charging material such as resin and after they are sprayed
from the gun 9, they move on an air stream 10 and adhere to the surface of the object
to be coated 3. In the case of the tribogun 9, no electrical field is generated between
the gun 9 and the object to be coated 3; therefore, the charged powder particles are
carried by the air stream 10 to the objected to be coated, without being influenced
by electrical field. This causes the coating film 5 to be formed also on the recessed
section of the object to be coated 3. In addition, since there is no electrical field
generated between the tribogun 9 and the object to be coated 3, no free ion problem,
which is observed with the corona gun, occurs.
[0006] Even when the tribogun 9 is used, however, a problem may arise. For example, if the
object to be coated 3 consists of an iron sheet covered with an undercoat insulating
layer and if a top coat layer is to be formed on the undercoat insulating layer, then
forming the charged powder may cause the potential on the surface to rise easily,
leading to the back ionization phenomenon. There is another problem in which the efficiency
of coating on the surface of the object to be coated 3 is lower than it is when the
corona gun is used.
[0007] The coating of an automotive body will be described as a typical example of multi-layer
coating which includes undercoat or the like. A coating film for a motorcar is constituted
by three or four multiple layers, the bottom layer being an electro-coat over which
a primer surfacer and a base coat or a clear top coat are to be formed. The powder
coating is applicable to the layers other than the electro-coat layer and the metallic
base coat. Superimposing such coating films, however, incurs much more electrostatic
restrictions than when coating a metallic object. This leads to such problems as lower
transfer efficiency and a coating film with rough surface.
[0008] For instance, when a high voltage of approximately -80 kV is applied to a coating
gun to coat an object which is provided with an undercoat, the surface of the undercoat
layer traps the charges of the ions coming from the coating gun, causing an increase
in the charge density on the surface of the object to be coated. For this reason,
the potential on the surface of the object to be coated reaches a high potential level
of a minus few kV and electrostatic repulsion takes place between the charged powder
particles injected from the coating gun toward the object to be coated, and the object
to be coated, resulting in lower transfer efficiency. The electrostatic repulsion
also takes place between the powder accumulated on the object to be coated. This tends
to give rise to appearance problems including rough surfaces of coating.
[0009] Thus, the conventional electrostatic powder coating method presents the problems
of the likelihood of the back ionization phenomenon which causes rough surfaces of
coating films and of low transfer efficiency of the powder coating.
SUMMARY OF THE INVENTION
[0010] The present invention has been achieved with a view toward solving the above problems.
It is an object of the present invention to provide a method and an apparatus for
electrostatic powder coating, whereby a good-quality coating surface can be formed
while improving the transfer efficiency of the powder coating at the same time.
[0011] To this end, according to the present invention, there is provided an electrostatic
powder coating method whereby charged powder supplied from a spray gun is applied
to the surface of an electrically grounded object to be coated. Further, free ions
in the vicinity of the spray gun are trapped and fine powder, which has a particle
size of 25 µm or less, is electrostatically charged and applied to the surface of
the object to be coated.
[0012] According to the present invention, there is also provided an apparatus for electrostatic
powder coating which is designed to electrostatically apply charged powder to the
surface of an electrically grounded object to be coated. The apparatus is provided
with an electrostatic gun for electrostatically charging fine-particle powder, which
has a particle size of 25 µm or less, and spraying the charged powder to the surface
of an object to be coated, and a free ion trapping device for trapping the free ions
in the vicinity of the electrostatic gun.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013]
Fig. 1 is a diagram showing a precharging step in the electrostatic powder coating
method of a first embodiment in accordance with the present invention;
Fig. 2 is a diagram showing a coating step in the electrostatic powder coating method
of the first embodiment;
Fig. 3 is a front view showing a free ion trapping device of a corona gun used in
the first embodiment;
Fig. 4 is a graph showing the relationship between the ion trapping distance and the
transfer efficiency of the free ion trapping device;
Fig. 5 is a graph showing the relationship between the pin layout and the transfer
efficiency of the free ion trapping device;
Fig. 6 is a cross-sectional view showing the tip of the nozzle of the spray gun used
for the electrostatic powder coating apparatus in a second embodiment;
Fig. 7 and Fig. 8 are cross-sectional views taken along line I-I and line II-II, respectively,
of Fig. 6;
Fig. 9 is a diagram showing the structure of the electrostatic powder coating apparatus
of a third embodiment;
Fig. 10 is a front view showing an electrical field generating electrode used in the
third embodiment;
Fig. 11 is a cross-sectional view showing an object to be coated, on which the transfer
efficiency was measured in the third embodiment;
Fig. 12 is a diagram showing the structure of the electrostatic powder coating apparatus
of a fourth embodiment;
Fig. 13 is a diagram showing an electrical field generating electrode used in a fifth
embodiment;
Fig. 14 is a diagram showing an electrical field generating electrode used in a sixth
embodiment;
Fig. 15 is a perspective view showing the spraying section of the electrostatic gun
used in a seventh embodiment;
Fig. 16 is a diagram showing an electrical field generating electrode used in the
seventh embodiment;
Fig. 17 is a schematic diagram showing the coating performed by a conventional corona
gun; and
Fig. 18 is a schematic diagram showing the coating performed by a conventional tribogun.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0014] The embodiments of the present invention will be described in conjunction with the
accompanying drawings.
First Embodiment:
[0015] The electrostatic powder coating method according to the first embodiment of the
present invention will be described with reference to Fig. 1 and Fig. 2.
[0016] An object to be coated 13 has an insulating layer 13b as an undercoat layer over
the surface of an iron plate 13a which is grounded. Before starting the electrostatic
coating to deposit a top coat layer on the undercoat insulating layer 13b, the surface
of the undercoat insulating layer 13 is exposed to an electrical field by using a
corona discharging device 30 so as to precharge the surface. Then, powder particles,
which have been negatively charged using a corona gun 11 shown in Fig. 2, are deposited
on the undercoat insulating layer 13b; therefore, in this step, the undercoat insulating
layer 13b is precharged with positive potential, i.e. it is precharged in the polarity
which is opposite from that of the charged powder particles. the corona discharging
device 30 is constructed by a corona electrode 31 and a high-voltage generating device
32 which applies positive high voltage to the corona electrode 31.
[0017] An appropriate surface potential of the precharged undercoat insulating layer 13b
can be selected by changing the applied voltage, the discharging distance, the discharging
time, etc.; the surface potential is set for about 200 V to about 3 kV.
[0018] In the next step, the negatively charged powder is deposited on the surface of the
undercoat insulating layer 13b of the object to be coated 13 by using the electrostatic
powder coating apparatus shown in Fig. 2 so as to produce the top coat layer. The
electrostatic powder coating apparatus is equipped with the corona gun 11 which employs
the external charging method. The corona gun 11 has a cylindrical gun main body 11a;
the central part of the tip of the gun main body 11a is provided with a pin-shaped
corona electrode 12 for generating an electrical field outside the gun 11 so as to
trigger corona discharge. A DC power source 15 connected applies high voltage to the
corona electrode 12. A free ion trapping device 16 is provided behind the corona electrode
12 on the outer periphery of the gun main body 11a. As shown in Fig. 3, the free ion
trapping device 16 has four grounded pin-shaped trapping electrodes 17 which are equidistantly
installed on the same circumference having the central axis of the corona gun 11 as
its center.
[0019] First, a high voltage of about -80 kV, for example, is applied from the DC power
source 15 to the corona electrode 12 of the corona gun 11 and the corona electrode
12 triggers corona discharge toward the object to be coated 13. At this time, since
the trapping electrodes 17 of the free ion trapping device 16 are provided near the
corona electrode 12, lines of electric force 18 concentrate on the trapping electrodes
17 and the majority of the free ions generated in the vicinity of the corona electrode
12 move along the lines of electric force 18 and they are trapped by the trapping
electrodes 17.
[0020] Under the condition stated above, when the power, which has a particle size of 25
µm or less, is carried by air and injected from the corona gun 11, the negative ions
produced by the corona discharge adhere to the powder particles to negatively charge
the powder particles. The negatively charged powder particles are guided primarily
by an air stream to the object to be coated 13 and they adhere to the surface of the
undercoat insulating layer 13b of the object to be coated 13.
[0021] At this time, the positive charge constituting the surface potential of the undercoat
insulating layer 13b and the negative charge of the charged powder particles countervail
each other for neutralization, thus preventing the coated surface from developing
such a high voltage that may cause back ionization. This allows a coating film with
outstanding finish to be produced. To ensure the formation of a smooth coating film
surface, it is preferable to use fine powder which has a particle diameter of 5 to
20 µm as the powder.
[0022] Since many free ions are trapped by the free ion trapping device 16, the number of
the free ions directed toward the object to be coated 13 is markedly decreased, making
it possible to prevent adverse influences attributable to free ions.
[0023] The undercoat insulating layer 13b may consist of two or more multiple layers rather
than a single layer.
[0024] Coating was carried out with different ion trapping distances D1 between the tip
of the corona electrode 12 and the tips of the trapping electrodes 17 shown in Fig.
2. The measurement results of the transfer efficiency obtained with the different
distances D1 are shown in Fig. 4. The gun voltage applied to the corona electrode
12 was set to -80 kV, the distance between the tip of the corona electrode 12 and
the object to be coated 13 was set to 200 mm, the powder feedrate was set to 75 g/min.,
and diameter D2 of the circle wherein the trapping electrodes 17 were installed as
shown in Fig. 3 was set to 154 mm. The measurement results have revealed that good
transfer efficiency is obtained at ion trapping distance D1 of 100 to 200 mm and that
approximately 150 mm, in particular, provides the best result.
[0025] Further, coating was carried out under different layouts of the trapping electrodes
17 of the free ion trapping apparatus 16, namely, A1 to A5. The measurement results
of the transfer efficiency obtained under the different layouts are shown in Fig.
5. These layouts A1 to A5 differ in diameter D2 of the circle and in the number of
the trapping electrodes as shown in Table 1 given below.
Table 1
Layout |
Circle Diameter D2 (mm) |
Number of Trapping Electrodes |
A1 |
80 |
4 |
A2 |
100 |
4 |
A3 |
125 |
4 |
A4 |
154 |
4 |
A5 |
154 |
8 |
[0026] For the purpose of this measurement, the gun voltage applied to the corona electrode
12 was set to -80 kV, the distance between the tip of the corona electrode 12 and
the object to be coated 13 was set to 200 mm, and the discharge of the powder was
set to 75 g/min. The measurement results have revealed that diameter D2 of the circle
on which the trapping electrodes 17 are laid out preferably ranges from 100 to 200
mm and that the best transfer efficiency is obtained at 154 mm in particular. No marked
difference was observed in the results of the measurement performed with four trapping
electrodes 17 and eight trapping electrodes 17, respectively.
[0027] Although the trapping electrodes 17 are grounded in this embodiment, a DC power supply
may be provided to apply a potential to the trapping electrodes 17.
Second Embodiment:
[0028] It is possible to apply a powder, which has a particle diameter of 25 µm or less,
preferably 5 to 20 µm, by using the electrostatic powder coating apparatus shown in
Fig. 6. A nozzle tip GN connected to a spray gun main body 110 is constructed by electrode
covers 101a, 101b, and 101c which respectively incorporate protective resistors for
safety, an inner cylinder 102 to which the electrode cover 101b is fixed with an electrode
supporting member 103, a diffuser 104 which also serves as an electrode tip cover,
a corona electrode 105 which is exposed 1 to 2 mm from the electrode tip cover 104,
and an outer cylinder 106.
[0029] The electrode covers 101a and 101b and the diffuser 104 are inserted in a power channel
FR of the nozzle tip GN; the distal end of the diffuser 104 is located in a nozzle
aperture 107. A section L of the powder channel FR where these members 101a, 101b,
and 104 are installed is made narrower.
[0030] The vertical cross-sectional area in the section L for carrying the coating is made
10% to 50% smaller than the radial cross-sectional area of a coating approach tube
109 so that the coating carrying speed increases in the section L. The side surface
of the inner cylinder 102 is provided with a plurality of vortex air inlets 108a and
108b which are formed in the tangential direction with respect to the powder channel
FR as shown in Fig. 7 and Fig. 8. An intersecting angle of the inlets 108a or 108b
which are adjacent to each other is set to an appropriate value, e.g. to 60 degrees.
[0031] During a coating operation, compressed air A is supplied through the voltex air inlets
108a and 108b, which communicate with the powder approach tube 109, in order to clean
the electrode cover 101c and the electrode supporting member 103.
[0032] Further, the free ion trapping device 16, which has a plurality of grounded trapping
electrodes 17, is provided around the outer periphery of the electrostatic gun main
body 110.
[0033] A high voltage of approximately -80 kV, for example, is applied to the corona electrode
105 and the corona electrode 105 triggers corona discharge toward an object to be
coated. At this time, the lines of electric force are concentrated onto the trapping
electrodes 17 and most of the free ions generated in the vicinity of the corona electrode
105 move along the lines of electric force and they are trapped by the trapping electrodes
17.
[0034] Under such a condition, fine-particle powder G having a particle diameter of 25 µm
or less is carried into the channel FR by carrying air H and compressed air A is supplied
through the vortex air inlets 108a and 108b. This causes the conveying air H to turn
into a flow of vortex air S around the central axis of the nozzle tip GN. The stream
S is accelerated due to the smaller aperture cross-sectional area in the section L,
then it collides with the diffuser 104 which spreads conically. This causes the aggregated
fine-particle G to be crushed and dispersed before it is sprayed through the nozzle
aperture 107. The fine-particle G is negatively charged by the negative ions generated
by the corona discharge, then it is sprayed to the object to be coated, thus producing
a uniform coating film.
Third Embodiment:
[0035] Fig. 9 shows the structure of an electrostatic powder coating apparatus according
to the third embodiment. The third embodiment has an electrical field generating electrode
21 which is provided between the corona gun 11 and the object to be coated 13 in the
apparatus of the first embodiment shown in Fig. 2. The electrical field generating
electrode 21 has a plurality of annular electrode members 23 which are laid out concentrically
on the surface of an insulating plate 22 with an aperture 22a formed in the center
thereof as illustrated in Fig. 10. These annular electrode members 23 are electrically
connected with each other and also connected to a DC power supply 24 as shown in Fig.
9. The DC power supply 24 is connected to the annular electrode members 23 in a polarity
which provides such an electrical field that causes the powder particles charged by
the corona gun 11 are attracted to the object to be coated 13, i.e. in the same polarity
as that of the DC power supply 15 connected to the corona electrode 12 of the corona
gun 11.
[0036] The operation of the third embodiment will now be described. First, the DC power
supply 15 applies a high voltage of about -80 kV, for example, to the corona electrode
12 of the corona gun 11 and the corona electrode 12 triggers corona discharge toward
the object to be coated 13. At this time, the lines of electric force 18 concentrate
onto the trapping electrodes 17 and most of the free ions generated near the corona
electrode 12 move along the lines of electric force 18 until they are trapped by the
trapping electrodes 17.Further, a potential of about -20 kV to about -40 kV is applied
from the DC power supply 24 to the plurality of annular electrode members 23 of the
electrical field generating electrode 21, thereby generating a nearly uniform electrical
field between the electrical field generating electrode 21 and the object to be coated
13.
[0037] When the powder is carried by air and injected from the corona gun 11 under such
a condition, the ions produced by the corona discharge adhere to the powder particles
to charge the powder particles which then move primarily on an air stream toward the
electrical field generating electrode 21. In this way, the charged powder particles
pass through the aperture 22a of the insulating plate 22 of the electrical field generating
electrode 21 and are attracted to the object to be coated 13 under the influences
exerted by the electrical field produced between the electrical field generating electrode
21 and the object to be coated 13, thereby adhering to the surface of the object to
be coated 13.
[0038] The third embodiment provides the following advantages: the number of free ions moving
toward the object to be coated 13 is markedly reduced due to the presence of the free
ion trapping device 16; the deterioration in the transfer efficiency due to an increase
of the surface potential of the object to be coated 13 and the rough surface of a
coating film caused by the back ionization phenomenon can be prevented; and the electrical
field which is provided between the electrical field generating electrode 21 and the
object to be coated 13 and which attracts charged powder particles makes it possible
to improve the efficiency of coating the surface of the object to be coated 13 even
if the number of free ions is decreased.
[0039] A single wide planar electrode member may be used in place of the plurality of annular
electrode members 23 of the electrical field generating electrode 21.
[0040] Using the coating apparatus of the third embodiment, the transfer efficiency was
measured under different values of potential E applied to the electrical field generating
electrode 21. As shown in Fig. 11, the object to be coated 13 had a primer surfacer
layer 13c which was comprised of a polyester powder and which was formed via the electrocoat
layer 13b over the iron plate 13a. A top coat layer 13d composed of an acrylic resin
powder, which had a mean particle diameter of 10 µm, was formed on the primer surfacer
layer 13c. The top coat layer 13d was formed under five different conditions 1 to
5 using the corona gun 11. Only under condition 1, the measurement was performed without
using the free ion trapping device 16. The voltage -80 kV applied to the corona electrode
and the discharge 75.2 g/min. of the powder coating were commonly set for all the
conditions. In the free ion trapping device 16, the ion trapping distance D1 between
the tip of the corona electrode 12 and the tips of the trapping electrodes 17 was
set to 150 mm and the diameter D2 of the circle on which the trapping electrodes 17
were installed was set to 154 mm. The distance d between the tip of the corona electrode
12 and the object to be coated was set to 200 mm or 150mm. Table 2 below shows the
measurement results of the transfer efficiency.
Table 2
Condition |
E(kV) |
Free Ion Trap |
Transfer Efficiency(%) |
|
|
|
d=200mm |
d=150mm |
1 |
0 |
Not Used |
68.2 |
72.2 |
2 |
0 |
Used |
75.2 |
81.0 |
3 |
-20 |
Used |
78.7 |
- |
4 |
-30 |
Used |
72.7 |
- |
5 |
-40 |
Used |
72.2 |
- |
[0041] The measurement results reveal that condition 3, wherein the potential of -20 kV
was applied to the electrical field generating electrode, presents the highest transfer
efficiency. Electrostatic repulsion was observed under condition 4 wherein the potential
of -30 kV was applied to the electrical field generating electrode and under condition
5 wherein the potential of -40 kV was applied to the electrical field generating electrode.
Fourth Embodiment:
[0042] Fig. 12 shows the structure of the electrostatic powder coating apparatus according
to the fourth embodiment. The fourth embodiment differs from the third embodiment
in that it employs a tribogun 19, which utilizes frictional electrification, in place
of the corona gun 11. The tribogun 19 includes a charging member composed of resin
or the like, so that powder is charged by the friction with the charging member as
it is transferred in the gun. The charging polarity is generally dependent on the
type of material such as resin which is used as the charging member. For instance,
when a charging member composed of Teflon is employed, the powder particles are charged
to the positive polarity. The tribogun 19 shown in Fig. 12 is designed to charge powder
particles to the positive polarity before spraying them. To draw the charged powder
particles to the object to be coated 13, the DC power supply 24 is connected to the
electrical field generating electrode 21 so that the polarity may be opposite from
that in the case of the third embodiment.
[0043] In the fourth embodiment wherein the positively charged powder particles are used,
prior to the electrostatic coating, the undercoat insulating layer 13b of the object
to be coated is precharged to the negative potential which is opposite from that of
the charged powder particles.
[0044] The positively charged powder, which has been spreyed from the tribogun 19, moves
on an air stream toward the induction field producing electrode 21 and passes through
the aperture 22a of the insulating plate 22 until it reaches the induction field generated
between the induction field producing electrode 21 and the object to be coated 13.
The powder particles are drawn to the object to be coated 13 due to the electrical
field and they adhere to the surface of the undercoat insulating layer 13b of the
object to be coated 13.
[0045] At this time, the negative charges constituting the surface potential of the undercoat
insulating layer 13b and the positive charges of the charged powder particles cancel
each other for neutralization. Hence, the coated surface does not develop such a high
voltage that triggers the back ionization, thus enabling the formation of a coating
film with outstanding finish.
[0046] In the fourth embodiment, the electrical field, which induces charged powder particles,
is generated between the electrical field generating electrode 21 and the object to
be coated 13. This makes it possible to efficiently coat the surface of the object
to be coated 13 by using the tribogun 19 as the electrostatic gun.
Fifth Embodiment:
[0047] Fig. 13 shows an electrical field generating electrode 31 of an electrostatic powder
coating apparatus according to the fifth embodiment. In the electrical field generating
electrode 31, annular electrode members 23 are formed on a surface 32a of an insulating
plate 32 made of a porous material. An air chamber 33 is formed on a rear surface
32b of the insulating plate 32, an air supplying device 34 being connected to the
air chamber 33.
[0048] In the fifth embodiment, compressed air is supplied from the air supplying device
34 to the air chamber 33 during coating operation. The air supplied to the air chamber
33 passes through the minute apertures of the porous material constituting the insulating
plate 32 and comes from the rear surface 32b out to a front surface 32a of the insulating
plate 32, then it is injected toward the object to be coated 13. This air jet keeps
the annular electrode members 23 clean at all times, thus preventing the charged powder
particles from sticking to the surfaces of the annular electrode members 23.
[0049] As the porous material for the insulating plate 32, a semi-sintered compact of a
ceramic, polyethylene or the like may be used. Forming an air curtain by the air jetted
from the insulating plate 32 to the object to be coated 13 makes it possible to keep
the powder, which is prone to be blown away by the carrying air stream, inside the
air curtain, thus further contributing to improved transfer efficiency.
Sixth Embodiment:
[0050] Fig. 14 shows an electrical field generating electrode 41 of an electrostatic powder
coating apparatus according to the sixth embodiment. In the electrical field generating
electrode 41, a predetermined potential is applied by a DC power supply 44 to a plurality
of annular electrode members 43 formed on the surface of an insulating plate 42. In
addition, an AC voltage is applied by an AC power supply 45 across the electrode members
43 which adjoin to each other. This construction enables an electrical field for inducing
charged powder particles to be generated between the electrical field generating electrode
41 and the object to be coated 13 by the DC power supply 44. Further, the application
of the AC voltage across the adjacent annular electrode members 43 causes silent discharge
on the surface of the electrical field generating electrode 41. The silent discharge
prevents the charged powder particles from sticking to the surface of the annular
electrode members 43.
Seventh Embodiment:
[0051] A gun 52, shown in Fig. 15, for linearly spraying powder is sometimes employed as
the spray gun. In this case, parallel linear electrode members 53 shown in Fig. 16
may be used in place of the annular electrodes for the electrical field generating
electrode.
[0052] In the third embodiment to the seventh embodiment, the safety can be improved by
using a conductor such as resin wire containing carbon which has a resistance of about
100 MΩ to 1000 MΩ for the electrode members 23, 43, and 53 employed for the electrical
field generating electrodes 21, 31, and 41.
[0053] An electrostatic powder coating method whereby free ions in the vicinity of a spray
gun are trapped and the fine powder, which has a particle diameter of 25 µm or less,
is electrostatically charged and applied to the surface of an electrically grounded
object to be coated. An electrostatic powder coating apparatus which is equipped with
an electrostatic gun for electrostatically charging fine powder, which has a particle
diameter of 25 µm or less, and spraying the charged fine powder to the surface of
the electrically grounded object to be coated, and a free ion trapping device for
trapping free ions near the electrostatic gun.
1. An electrostatic powder coating method for applying charged powder supplied from a
spray gun to the surface of an electrically grounded object to be coated, comprising
the steps of:
trapping a free ion in the vicinity of the spray gun; and
electrostatically charging fine powder which has a particle diameter of 25 µm or
less and applying it to the surface of the object to be coated.
2. An electrostatic powder coating method according to Claim 1, wherein charged powder
is applied to the surface of the object to be coated, the object having an undercoat
layer.
3. An electrostatic powder coating method according to Claim 2, wherein the undercoat
layer is a single layer.
4. An electrostatic powder coating method according to Claim 2, wherein the undercoat
layer is a multi-layer of two layers or more.
5. An electrostatic powder coating method according to Claim 2, further comprising the
step of precharging the surface of the undercoat layer by exposing the surface of
the object to be coated to an electrical field of a polarity which is opposite from
that of the charged powder.
6. An electrostatic powder coating method according to Claim 5, wherein the surface of
the undercoat layer of the object to be coated is precharged by making use of corona
discharge.
7. An electrostatic powder coating method according to Claim 1, wherein the fine powder
has a particle diameter of 5 to 20 µm.
8. An electrostatic powder coating method according to Claim 1, further comprising the
step of forming an almost uniform induction field for inducing the charged powder
to the surface of the object to be coated in the vicinity of the surface of the object
to be coated.
9. An electrostatic powder coating method according to Claim 1, wherein the powder is
supplied from the spray gun while the powder is being turned.
10. An electrostatic powder coating apparatus for electrostatically applying charged powder
to the surface of an electrically grounded object to be coated, comprising:
an electrostatic gun for electrostatically charging fine powder, which has a particle
diameter of 25 µm or less, and spraying it to the surface of the object to be coated;
and
a free ion trapping device for trapping a free ion near the electrostatic gun.
11. An apparatus according to Claim 10, wherein the electrostatic gun comprises:
a nozzle for spraying the powder;
a corona electrode provided on the tip of the nozzle for triggering corona discharge;
and
a first DC power supply for applying high voltage to the corona electrode.
12. An apparatus according to Claim 11, wherein the free ion trapping device includes
a plurality of grounded pin-shaped trapping electrodes provided on an outer peripheral
section of the nozzle behind the corona electrode and equidistantly laid out on the
same circumference centering around an axis which passes through the corona electrode.
13. An apparatus according to Claim 12, wherein the trapping electrodes are disposed so
that the distance between the tip of the corona electrode and the tips of the trapping
electrodes becomes 100 to 200 mm.
14. An apparatus according to Claim 12, wherein the trapping electrodes are disposed on
the same circumference measuring 100 to 200 mm in diameter.
15. An apparatus according to Claim 12, wherein the number of the trapping electrodes
is four or more and the distance between the tip of the corona electrode and tips
of the trapping electrodes is 120 to 150 mm.
16. An apparatus according to Claim 11, wherein the electrostatic gun includes turning
and spraying means for spraying the powder while turning it around the central axis
of the nozzle.
17. An apparatus according to Claim 16, wherein the turning and spraying means comprises:
means for carrying the powder toward the central axis of the nozzle by using a
carrying air stream; and
means for forming a turning stream by supplying compressed air in the tangential
direction in relation to a carrying channel for the powder.
18. An apparatus according to Claim 17, wherein the electrostatic gun includes a conical
diffuser provided in a powder channel at the tip of the nozzle.
19. An apparatus according to Claim 18, wherein the edge of the diffuser is recessed from
the tip of the nozzle.
20. An apparatus according to Claim 10, further comprising:
an electrical field generating electrode disposed between the electrostatic gun
and the object to be coated; and
a second DC power supply for generating an electrical field for applying a predetermined
potential to the electrical field generating electrode to produce an electrical field
between the electrical field generating electrode and the object to be coated so as
to form an electrical field for guiding the charged powder to the surface of the object
to be coated.
21. An apparatus according to Claim 20, wherein the electrical field generating electrode
includes:
an insulating plate which has an aperture at the center thereof for allowing the
powder sprayed from the electrostatic gun to pass through it; and
a plurality of annular electrode members which are laid out concentrically on the
surface of the insulating plate.
22. An apparatus according to Claim 21, further comprising air supplying means for spurting
air through the insulating plate composed of a porous member from the rear surface
to the front surface of the insulating plate.
23. An apparatus according to Claim 21, further comprising an AC power supply for applying
AC voltage across adjoining annular electrode members so as to trigger silent discharge.
24. An apparatus according to Claim 11, wherein the free ion trapping device includes
a plurality of pin-shaped trapping electrodes provided on an outer peripheral section
of the nozzle behind the corona electrode and equidistantly laid out on the same circumference
centering around an axis which passes through the corona electrode, and a DC power
supply for applying a potential to the trapping electrodes.